{"title":"在横断面肌肉图像中自动深入纤维和细胞核分型可以为更好地理解骨骼肌疾病铺平道路","authors":"Simone Baltrusch","doi":"10.1111/apha.14031","DOIUrl":null,"url":null,"abstract":"<p>In this issue of <i>Acta Physiologica</i>, Lundquist et al.<span><sup>1</sup></span> present a new platform for automated image data analysis of skeletal muscle samples. Immunohistochemical analysis can be used to visualize the fiber type composition of different skeletal muscles and their sex-specific adaptations with age, which are individually influenced by genetic predisposition, physical exercise, nutrition, stress, and environmental factors (Figure 1). Because of the correlation of muscle structure and physiology, the assessment can also provide an important contribution to the evaluation of diseased tissue. Over the past 5 years various image data analysis software have been developed that allow automated evaluation of immunohistochemical skeletal muscle cross-sectional images. Manual assessment limits the quantitative result in terms of representativeness, since only a small number of samples can be investigated due to the time required, and in terms of objectivity, which is highly dependent on the qualifications of the evaluator. In the future, automation of image data analysis will be crucial to compare results of skeletal muscle samples of animal models as well as on human biopsies from different research institutions and clinical centers. If the quality of sample preparation and microscopy is ensured, it would be possible to build global databases that could be used, for example, to improve the evaluation and therapy of rare muscle diseases—a worthwhile goal.</p><p>Some of the available evaluation routines for skeletal muscle cross-sectional images were programmed directly in MatLab (e.g., MyoView<span><sup>2</sup></span>) or performed with paid software (e.g., Imaris<span><sup>3</sup></span>). However, two open source image processing packages are mainly used in the community to analyze image data. One of these is Fiji/ImageJ, which was developed based on JAVA by an employee of the NIH and is constantly being expanded by a large team. Of the hundreds of plug-ins now written by the user community, Myosight,<span><sup>4</sup></span> MuscleJ,<span><sup>5</sup></span> Myosoft,<span><sup>6</sup></span> MyoVision,<span><sup>7</sup></span> QauntiMus<span><sup>8</sup></span> and one more macro<span><sup>9</sup></span> are available for the analysis of cross-sectional muscle samples. CellProfiler was created at the Broad Institute of MIT and Harvard and is permanently being improved there by a project team in the Cimini Lab. The software, written in Python, is thus also a free, open-source project into which anyone can write their own image processing algorithms as a new module. So far, Muscle2view<span><sup>10</sup></span> has been developed to evaluate cross-sectional samples of muscle based on CellProfiler. Lundquist et al. now introduce FiNuTyper (Fiber and Nucleus Typer) as a new module<span><sup>1</sup></span> (Figure 2). The question arises, which novel possibilities FiNuTyper opens for the evaluation of muscle cross-section samples compared to the already available image processing packages.</p><p>Fiber identification, typing and size determination is available in all the mentioned software modules. By integrating Cellpose,<span><sup>11</sup></span> an algorithm developed in Python based on machine object recognition, the authors were able to improve the accuracy of fiber detection compared to the already available software algorithms. Furthermore, FiNuTyper is the first tool to allow automatic detection of fiber groupings defined as collections of the same fiber type (Figure 2). This parameter seems to play a role especially in slow-twitch muscle fibers. Here, an increase in such fiber groupings may be a marker for reinnervated muscle fibers and reflect activity-related plasticity.</p><p>Whereas differentiation of slow- and fast-twitch muscle fibers has previously been performed using antibodies to detect the distribution of myosin heavy chains (MyHC), Lundquist et al. take a different approach.<span><sup>1</sup></span> The authors aimed to simultaneously perform differential nucleotyping, which is not possible via contractile protein labeling. In the entire family of Ca<sup>2+</sup>-ATPases, three work as sarcoplasmic reticulum Ca<sup>2+</sup> pumps (SERCA).<span><sup>12</sup></span> SERCA1 is expressed only in fast-twitch skeletal muscle.<span><sup>12</sup></span> SERCA2 is found in fast- and slow-twitch, smooth, and cardiac muscle as well as in non-muscle cells.<span><sup>12</sup></span> SERCA3, on the other hand, is found solely in non-muscle cells.<span><sup>12</sup></span> The nuclear envelope, which physically separates nucleoplasm from cytoplasm, is interrupted by a complex branched network of invaginations, the nucleoplasmic reticulum. Among many other functions, these structures control the selective bidirectional transport of ions. Ca<sup>2+</sup> transport is also under the control of SERCA, as has been shown in cardiomyocytes.<span><sup>13</sup></span> Disruption of nucleoplasmic Ca<sup>2+</sup> signaling appears to trigger the development of hypertrophy and heart failure at an early stage.<span><sup>13</sup></span> With the selection of appropriate SERCA antibodies and detailed comparison to established MyHC1 and MyHC2A immunohistochemistry, the authors convince that SERCA1 is a sensitive and specific marker for type 2 muscle fibers and SERCA2 for type 1. Furthermore, Lundquist et al.<span><sup>1</sup></span> were able to demonstrate the quality of this new methodological approach in both healthy and pathological tissue.</p><p>The detection of nuclei using SERCA isoforms has the advantage that exclusively myonuclei can be detected and thus distinguished from the mononuclei of blood vessel cells, fibroblasts and satellite cells. Since satellite cells are the resource for fiber growth and the number of myonuclei per myofiber allows statements about the condition of a muscle (e.g., atrophy),<span><sup>14</sup></span> this method is clearly superior in its informative value to the established nuclear staining using DAPI. By incorporating another deep learning algorithm, nucleAIzer,<span><sup>15</sup></span> the detection of nuclei itself in FiNuTyper<span><sup>1</sup></span> is further improved. The distribution of myonuclei within the muscle fiber plays an essential role in their supply and regulation,<span><sup>16</sup></span> but mechanisms for their motility, increase, and degradation are poorly understood to date.<span><sup>16</sup></span> Since nucleotyping can clearly specify statements about the health status of a muscle in addition to fiber typing, the search for a specific marker has been the subject of research for some time. The protein pericentriolar material 1 has been shown to be a specific marker of post-mitotic myonuclei.<span><sup>14</sup></span> However, the detection via SERCA isoforms presented by Lundquist et al.<span><sup>1</sup></span> provides two advantages over this labeling. A specific nuclear assignment to the fiber type and the evaluation of myonuclei and fiber type in the same tissue section.</p><p>The authors provide an initial promising evaluation of muscle tissue from patients with amyotrophic lateral sclerosis and inclusion body myositis using FiNuTyper.<span><sup>1</sup></span> As Lloyd et al.<span><sup>17</sup></span> conclude in a review just published in <i>Acta Physiologica</i>, the process of change in muscle fiber type triggered by different endogenous and environmental factors, characterizes the manifestation of a variety of neuromuscular diseases. Slow- and fast-twitch muscle fibers show different susceptibility to stressors<span><sup>1, 17</sup></span> (Figure 1). Due to various routines in the acquisition and evaluation of image data, published results can unfortunately often only be compared inadequately. This makes the characterization of disease patterns difficult. Considering this fact, FiNuTyper<span><sup>1</sup></span> could make a significant contribution here. However, only broader application will show whether the platform meets expectations or needs further improvement.</p><p><b>Simone Baltrusch:</b> Conceptualization; writing – original draft.</p><p>None.</p><p>Research in the authors lab is supported by the DFG (GRK 2676) and Deutsche Diabetes Gesellschaft.</p><p>The author has no conflicts of interest to disclose.</p>","PeriodicalId":107,"journal":{"name":"Acta Physiologica","volume":"239 1","pages":""},"PeriodicalIF":5.6000,"publicationDate":"2023-08-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/apha.14031","citationCount":"0","resultStr":"{\"title\":\"Automated in-depth fiber and nuclei typing in cross-sectional muscle images can pave the way to a better understanding of skeletal muscle diseases\",\"authors\":\"Simone Baltrusch\",\"doi\":\"10.1111/apha.14031\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>In this issue of <i>Acta Physiologica</i>, Lundquist et al.<span><sup>1</sup></span> present a new platform for automated image data analysis of skeletal muscle samples. Immunohistochemical analysis can be used to visualize the fiber type composition of different skeletal muscles and their sex-specific adaptations with age, which are individually influenced by genetic predisposition, physical exercise, nutrition, stress, and environmental factors (Figure 1). Because of the correlation of muscle structure and physiology, the assessment can also provide an important contribution to the evaluation of diseased tissue. Over the past 5 years various image data analysis software have been developed that allow automated evaluation of immunohistochemical skeletal muscle cross-sectional images. Manual assessment limits the quantitative result in terms of representativeness, since only a small number of samples can be investigated due to the time required, and in terms of objectivity, which is highly dependent on the qualifications of the evaluator. In the future, automation of image data analysis will be crucial to compare results of skeletal muscle samples of animal models as well as on human biopsies from different research institutions and clinical centers. If the quality of sample preparation and microscopy is ensured, it would be possible to build global databases that could be used, for example, to improve the evaluation and therapy of rare muscle diseases—a worthwhile goal.</p><p>Some of the available evaluation routines for skeletal muscle cross-sectional images were programmed directly in MatLab (e.g., MyoView<span><sup>2</sup></span>) or performed with paid software (e.g., Imaris<span><sup>3</sup></span>). However, two open source image processing packages are mainly used in the community to analyze image data. One of these is Fiji/ImageJ, which was developed based on JAVA by an employee of the NIH and is constantly being expanded by a large team. Of the hundreds of plug-ins now written by the user community, Myosight,<span><sup>4</sup></span> MuscleJ,<span><sup>5</sup></span> Myosoft,<span><sup>6</sup></span> MyoVision,<span><sup>7</sup></span> QauntiMus<span><sup>8</sup></span> and one more macro<span><sup>9</sup></span> are available for the analysis of cross-sectional muscle samples. CellProfiler was created at the Broad Institute of MIT and Harvard and is permanently being improved there by a project team in the Cimini Lab. The software, written in Python, is thus also a free, open-source project into which anyone can write their own image processing algorithms as a new module. So far, Muscle2view<span><sup>10</sup></span> has been developed to evaluate cross-sectional samples of muscle based on CellProfiler. Lundquist et al. now introduce FiNuTyper (Fiber and Nucleus Typer) as a new module<span><sup>1</sup></span> (Figure 2). The question arises, which novel possibilities FiNuTyper opens for the evaluation of muscle cross-section samples compared to the already available image processing packages.</p><p>Fiber identification, typing and size determination is available in all the mentioned software modules. By integrating Cellpose,<span><sup>11</sup></span> an algorithm developed in Python based on machine object recognition, the authors were able to improve the accuracy of fiber detection compared to the already available software algorithms. Furthermore, FiNuTyper is the first tool to allow automatic detection of fiber groupings defined as collections of the same fiber type (Figure 2). This parameter seems to play a role especially in slow-twitch muscle fibers. Here, an increase in such fiber groupings may be a marker for reinnervated muscle fibers and reflect activity-related plasticity.</p><p>Whereas differentiation of slow- and fast-twitch muscle fibers has previously been performed using antibodies to detect the distribution of myosin heavy chains (MyHC), Lundquist et al. take a different approach.<span><sup>1</sup></span> The authors aimed to simultaneously perform differential nucleotyping, which is not possible via contractile protein labeling. In the entire family of Ca<sup>2+</sup>-ATPases, three work as sarcoplasmic reticulum Ca<sup>2+</sup> pumps (SERCA).<span><sup>12</sup></span> SERCA1 is expressed only in fast-twitch skeletal muscle.<span><sup>12</sup></span> SERCA2 is found in fast- and slow-twitch, smooth, and cardiac muscle as well as in non-muscle cells.<span><sup>12</sup></span> SERCA3, on the other hand, is found solely in non-muscle cells.<span><sup>12</sup></span> The nuclear envelope, which physically separates nucleoplasm from cytoplasm, is interrupted by a complex branched network of invaginations, the nucleoplasmic reticulum. Among many other functions, these structures control the selective bidirectional transport of ions. Ca<sup>2+</sup> transport is also under the control of SERCA, as has been shown in cardiomyocytes.<span><sup>13</sup></span> Disruption of nucleoplasmic Ca<sup>2+</sup> signaling appears to trigger the development of hypertrophy and heart failure at an early stage.<span><sup>13</sup></span> With the selection of appropriate SERCA antibodies and detailed comparison to established MyHC1 and MyHC2A immunohistochemistry, the authors convince that SERCA1 is a sensitive and specific marker for type 2 muscle fibers and SERCA2 for type 1. Furthermore, Lundquist et al.<span><sup>1</sup></span> were able to demonstrate the quality of this new methodological approach in both healthy and pathological tissue.</p><p>The detection of nuclei using SERCA isoforms has the advantage that exclusively myonuclei can be detected and thus distinguished from the mononuclei of blood vessel cells, fibroblasts and satellite cells. Since satellite cells are the resource for fiber growth and the number of myonuclei per myofiber allows statements about the condition of a muscle (e.g., atrophy),<span><sup>14</sup></span> this method is clearly superior in its informative value to the established nuclear staining using DAPI. By incorporating another deep learning algorithm, nucleAIzer,<span><sup>15</sup></span> the detection of nuclei itself in FiNuTyper<span><sup>1</sup></span> is further improved. The distribution of myonuclei within the muscle fiber plays an essential role in their supply and regulation,<span><sup>16</sup></span> but mechanisms for their motility, increase, and degradation are poorly understood to date.<span><sup>16</sup></span> Since nucleotyping can clearly specify statements about the health status of a muscle in addition to fiber typing, the search for a specific marker has been the subject of research for some time. The protein pericentriolar material 1 has been shown to be a specific marker of post-mitotic myonuclei.<span><sup>14</sup></span> However, the detection via SERCA isoforms presented by Lundquist et al.<span><sup>1</sup></span> provides two advantages over this labeling. A specific nuclear assignment to the fiber type and the evaluation of myonuclei and fiber type in the same tissue section.</p><p>The authors provide an initial promising evaluation of muscle tissue from patients with amyotrophic lateral sclerosis and inclusion body myositis using FiNuTyper.<span><sup>1</sup></span> As Lloyd et al.<span><sup>17</sup></span> conclude in a review just published in <i>Acta Physiologica</i>, the process of change in muscle fiber type triggered by different endogenous and environmental factors, characterizes the manifestation of a variety of neuromuscular diseases. Slow- and fast-twitch muscle fibers show different susceptibility to stressors<span><sup>1, 17</sup></span> (Figure 1). Due to various routines in the acquisition and evaluation of image data, published results can unfortunately often only be compared inadequately. This makes the characterization of disease patterns difficult. Considering this fact, FiNuTyper<span><sup>1</sup></span> could make a significant contribution here. 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引用次数: 0
摘要
在这一期的《生理学报》中,Lundquist等人1提出了一个用于骨骼肌样本自动图像数据分析的新平台。免疫组织化学分析可用于可视化不同骨骼肌的纤维类型组成及其随年龄的性别特异性适应,这些纤维类型组成分别受到遗传易感性、体育锻炼、营养、压力和环境因素的影响(图1)。由于肌肉结构和生理的相关性,该评估也可以为病变组织的评估提供重要贡献。在过去的5年中,各种图像数据分析软件已经开发出来,可以自动评估免疫组织化学骨骼肌横断面图像。人工评估在代表性方面限制了定量结果,因为由于需要时间,只能调查少量样本,而在客观性方面,这高度依赖于评估者的资格。在未来,图像数据分析的自动化对于比较来自不同研究机构和临床中心的动物模型骨骼肌样本以及人体活检的结果至关重要。如果样品制备和显微镜的质量得到保证,就有可能建立全球数据库,例如,用于改进罕见肌肉疾病的评估和治疗——这是一个有价值的目标。一些可用的骨骼肌横截面图像评估例程直接在MatLab中编程(例如,MyoView2)或使用付费软件(例如,Imaris3)执行。然而,社区主要使用两个开源图像处理包来分析图像数据。其中之一是Fiji/ImageJ,它是由美国国立卫生研究院的一名雇员基于JAVA开发的,并由一个大型团队不断扩展。在用户社区编写的数百个插件中,Myosight、4个MuscleJ、5个Myosoft、6个MyoVision、7个QauntiMus8和另外一个macro9可用于分析横截面肌肉样本。CellProfiler是由麻省理工学院和哈佛大学的Broad研究所创建的,并由Cimini实验室的一个项目团队永久地改进。该软件是用Python编写的,因此也是一个免费的开源项目,任何人都可以在其中编写自己的图像处理算法作为一个新的模块。到目前为止,Muscle2view10已经开发用于评估基于CellProfiler的肌肉横截面样本。Lundquist等人现在引入了FiNuTyper (Fiber and Nucleus Typer)作为一个新的模块1(图2)。问题出现了,与现有的图像处理软件包相比,FiNuTyper为肌肉横截面样本的评估开辟了哪些新的可能性。在上述所有软件模块中都可以进行纤维识别、分类和尺寸测定。通过集成Cellpose(一种用Python开发的基于机器对象识别的算法),与现有的软件算法相比,作者能够提高纤维检测的准确性。此外,FiNuTyper是第一个允许自动检测被定义为相同纤维类型集合的纤维分组的工具(图2)。该参数似乎在慢肌纤维中发挥了作用。在这里,这种纤维群的增加可能是再神经支配肌纤维的标志,反映了与活动相关的可塑性。尽管之前已经使用抗体检测肌球蛋白重链(MyHC)的分布来区分慢肌纤维和快肌纤维,但Lundquist等人采用了不同的方法作者旨在同时进行差异核分型,这是不可能通过收缩蛋白标记。在整个Ca2+- atp酶家族中,有三种作为肌浆网Ca2+泵(SERCA)SERCA1仅在快速收缩骨骼肌中表达SERCA2存在于快肌和慢肌、平滑肌和心肌以及非肌肉细胞中另一方面,SERCA3仅存在于非肌肉细胞中物理上将核质与细胞质分离的核膜被一个复杂的分支内陷网络——核质网所中断。在许多其他功能中,这些结构控制离子的选择性双向传输。Ca2+转运也受SERCA的控制,这在心肌细胞中已经得到证实核质Ca2+信号的破坏似乎会在早期引发肥厚和心力衰竭的发展通过选择合适的SERCA抗体,并与已建立的MyHC1和MyHC2A免疫组化进行详细比较,作者确信SERCA1是2型肌纤维的敏感和特异性标志物,SERCA2是1型肌纤维的特异性标志物。此外,Lundquist等人1能够在健康和病理组织中证明这种新方法的质量。 使用SERCA同种异构体检测细胞核的优点是可以检测到单独的肌核,从而与血管细胞、成纤维细胞和卫星细胞的单核细胞区分开来。由于卫星细胞是纤维生长的资源,每条肌纤维的肌核数量可以判断肌肉的状况(例如,萎缩),14这种方法在信息价值上明显优于使用DAPI建立的核染色。通过结合另一种深度学习算法nucleAIzer 15, FiNuTyper1中原子核本身的检测得到了进一步改进。肌核在肌纤维中的分布在其供应和调节中起着至关重要的作用,但其运动、增加和降解的机制迄今尚不清楚由于核分型除了纤维分型外,还能清楚地说明肌肉的健康状况,因此寻找一种特定的标记物已经成为一段时间以来的研究主题。中心粒周围蛋白物质已被证明是有丝分裂后核分裂的特异性标记物然而,Lundquist等人1提出的通过SERCA异构体进行检测比这种标记有两个优点。在同一组织切片中对纤维类型和肌核和纤维类型的具体核分配和评价。作者使用finutype对肌萎缩性侧索硬化症和包涵体肌炎患者的肌肉组织进行了初步的有希望的评估正如Lloyd et al.17在刚刚发表在Acta physi上的一篇综述中所总结的那样,由不同内源性和环境因素引发的肌纤维类型变化过程是多种神经肌肉疾病表现的特征。慢肌纤维和快肌纤维对压力源表现出不同的敏感性1,17(图1)。由于图像数据的获取和评估方法不同,不幸的是,已发表的结果往往只能进行不充分的比较。这使得疾病模式的表征变得困难。考虑到这一事实,FiNuTyper1可以在这里做出重大贡献。然而,只有更广泛的应用才能证明该平台是否达到了预期,还是需要进一步改进。Simone Baltrusch:概念化;作者实验室的研究得到了DFG (GRK 2676)和德国糖尿病协会的支持。作者没有需要披露的利益冲突。
Automated in-depth fiber and nuclei typing in cross-sectional muscle images can pave the way to a better understanding of skeletal muscle diseases
In this issue of Acta Physiologica, Lundquist et al.1 present a new platform for automated image data analysis of skeletal muscle samples. Immunohistochemical analysis can be used to visualize the fiber type composition of different skeletal muscles and their sex-specific adaptations with age, which are individually influenced by genetic predisposition, physical exercise, nutrition, stress, and environmental factors (Figure 1). Because of the correlation of muscle structure and physiology, the assessment can also provide an important contribution to the evaluation of diseased tissue. Over the past 5 years various image data analysis software have been developed that allow automated evaluation of immunohistochemical skeletal muscle cross-sectional images. Manual assessment limits the quantitative result in terms of representativeness, since only a small number of samples can be investigated due to the time required, and in terms of objectivity, which is highly dependent on the qualifications of the evaluator. In the future, automation of image data analysis will be crucial to compare results of skeletal muscle samples of animal models as well as on human biopsies from different research institutions and clinical centers. If the quality of sample preparation and microscopy is ensured, it would be possible to build global databases that could be used, for example, to improve the evaluation and therapy of rare muscle diseases—a worthwhile goal.
Some of the available evaluation routines for skeletal muscle cross-sectional images were programmed directly in MatLab (e.g., MyoView2) or performed with paid software (e.g., Imaris3). However, two open source image processing packages are mainly used in the community to analyze image data. One of these is Fiji/ImageJ, which was developed based on JAVA by an employee of the NIH and is constantly being expanded by a large team. Of the hundreds of plug-ins now written by the user community, Myosight,4 MuscleJ,5 Myosoft,6 MyoVision,7 QauntiMus8 and one more macro9 are available for the analysis of cross-sectional muscle samples. CellProfiler was created at the Broad Institute of MIT and Harvard and is permanently being improved there by a project team in the Cimini Lab. The software, written in Python, is thus also a free, open-source project into which anyone can write their own image processing algorithms as a new module. So far, Muscle2view10 has been developed to evaluate cross-sectional samples of muscle based on CellProfiler. Lundquist et al. now introduce FiNuTyper (Fiber and Nucleus Typer) as a new module1 (Figure 2). The question arises, which novel possibilities FiNuTyper opens for the evaluation of muscle cross-section samples compared to the already available image processing packages.
Fiber identification, typing and size determination is available in all the mentioned software modules. By integrating Cellpose,11 an algorithm developed in Python based on machine object recognition, the authors were able to improve the accuracy of fiber detection compared to the already available software algorithms. Furthermore, FiNuTyper is the first tool to allow automatic detection of fiber groupings defined as collections of the same fiber type (Figure 2). This parameter seems to play a role especially in slow-twitch muscle fibers. Here, an increase in such fiber groupings may be a marker for reinnervated muscle fibers and reflect activity-related plasticity.
Whereas differentiation of slow- and fast-twitch muscle fibers has previously been performed using antibodies to detect the distribution of myosin heavy chains (MyHC), Lundquist et al. take a different approach.1 The authors aimed to simultaneously perform differential nucleotyping, which is not possible via contractile protein labeling. In the entire family of Ca2+-ATPases, three work as sarcoplasmic reticulum Ca2+ pumps (SERCA).12 SERCA1 is expressed only in fast-twitch skeletal muscle.12 SERCA2 is found in fast- and slow-twitch, smooth, and cardiac muscle as well as in non-muscle cells.12 SERCA3, on the other hand, is found solely in non-muscle cells.12 The nuclear envelope, which physically separates nucleoplasm from cytoplasm, is interrupted by a complex branched network of invaginations, the nucleoplasmic reticulum. Among many other functions, these structures control the selective bidirectional transport of ions. Ca2+ transport is also under the control of SERCA, as has been shown in cardiomyocytes.13 Disruption of nucleoplasmic Ca2+ signaling appears to trigger the development of hypertrophy and heart failure at an early stage.13 With the selection of appropriate SERCA antibodies and detailed comparison to established MyHC1 and MyHC2A immunohistochemistry, the authors convince that SERCA1 is a sensitive and specific marker for type 2 muscle fibers and SERCA2 for type 1. Furthermore, Lundquist et al.1 were able to demonstrate the quality of this new methodological approach in both healthy and pathological tissue.
The detection of nuclei using SERCA isoforms has the advantage that exclusively myonuclei can be detected and thus distinguished from the mononuclei of blood vessel cells, fibroblasts and satellite cells. Since satellite cells are the resource for fiber growth and the number of myonuclei per myofiber allows statements about the condition of a muscle (e.g., atrophy),14 this method is clearly superior in its informative value to the established nuclear staining using DAPI. By incorporating another deep learning algorithm, nucleAIzer,15 the detection of nuclei itself in FiNuTyper1 is further improved. The distribution of myonuclei within the muscle fiber plays an essential role in their supply and regulation,16 but mechanisms for their motility, increase, and degradation are poorly understood to date.16 Since nucleotyping can clearly specify statements about the health status of a muscle in addition to fiber typing, the search for a specific marker has been the subject of research for some time. The protein pericentriolar material 1 has been shown to be a specific marker of post-mitotic myonuclei.14 However, the detection via SERCA isoforms presented by Lundquist et al.1 provides two advantages over this labeling. A specific nuclear assignment to the fiber type and the evaluation of myonuclei and fiber type in the same tissue section.
The authors provide an initial promising evaluation of muscle tissue from patients with amyotrophic lateral sclerosis and inclusion body myositis using FiNuTyper.1 As Lloyd et al.17 conclude in a review just published in Acta Physiologica, the process of change in muscle fiber type triggered by different endogenous and environmental factors, characterizes the manifestation of a variety of neuromuscular diseases. Slow- and fast-twitch muscle fibers show different susceptibility to stressors1, 17 (Figure 1). Due to various routines in the acquisition and evaluation of image data, published results can unfortunately often only be compared inadequately. This makes the characterization of disease patterns difficult. Considering this fact, FiNuTyper1 could make a significant contribution here. However, only broader application will show whether the platform meets expectations or needs further improvement.
Simone Baltrusch: Conceptualization; writing – original draft.
None.
Research in the authors lab is supported by the DFG (GRK 2676) and Deutsche Diabetes Gesellschaft.
The author has no conflicts of interest to disclose.
期刊介绍:
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